DE2460071C3 - Borehole measuring arrangement - Google Patents

Description

ίο The invention relates to a borehole measuring arrangement in the preamble of claim 1 mentioned Art.

In an older such borehole measuring arrangement (DE-PS 22 21718) is on the inner conductor of the Coaxial cable, a signal formed by adding up data and reference signals to that of the surface Transfer provided device, and also serves the inner conductor to a high DC voltage from the device arranged above ground to the probe transfer. Another DC voltage is applied via the Transfer the shield to the probe.

There is already a coaxial cable for use in borehole measurements known (US-PS 36 02 632) the isolated conductor groups within the outer armouring of the cable are provided. To the In this known coaxial cable, the purpose of shielding is to use special shielding compounds in the spaces between the conductor groups imprinted

According to another of our own older proposal (DE-PS 24 33 492), an inner conductor is made. Shield and outer armor existing coaxial cable is used, and there are two in the probe generated measurement signals interleaved in time via one and the same inner conductor of the coaxial cable supplied to the facility arranged above ground

The invention is based on the object of designing the borehole measuring arrangement so that - without the need for a unified intertwining nesting of measurement signals - at least one further measuring signal can be transmitted in front of the measuring probe to the device arranged above ground

This object is achieved by the features specified in the characterizing part of claim 1.

In the borehole measuring arrangement according to the invention, the conductor groups on the one hand have the function of a Forming a shield for the high frequency data signal; on the other hand, each group of leaders stands for itself the transmission of a low-frequency signal or a DC voltage available, the outer Reinforcement serves as the opposite pole. This enables a very economical use of the conductor groups forming the high-frequency shielding An embodiment of the invention from which further details are shown in the drawing shown. It shows

1 shows a simplified block diagram of a borehole measuring system with an armored multi-conductor coaxial cable,

Fi g. 2A and 2B representations of that shown in FIG Multi-conductor coaxial cable and

F i g. 3 shows a schematic representation of a distribution circuit according to FIG. 1.

In FIG. 1 is a measuring probe 1 in a borehole

brought down. The measuring probe 1 can have a neutron source 5, a crystal detector 8, a preamplifier 9, and an electronic switching part 15 have. That electronic switching part 15 is for the Überraeune of

Impulses or signals are provided after days and can have a stabilizing pulse generator that generates comparison pulses. The measuring probe can furthermore a conventional finder 17 for the connection sleeves and a distributor circuit 20 exhibit.

The operation of these elements, with the exception of the distribution circuit, is well known and a detailed description would be repetitive within the scope of this invention. It is sufficient to remember that the neutron source 5 bombarded the formation with neutrons, resulting in gamma rays which are detected by the crystal detector 8. It is evident to a person skilled in the art that the neutron source 5 can be omitted and the natural gamma radiation can be determined directly for this purpose. The preamplifier 9 amplifies the pulse signals of the detector 8 in accordance with the detected radiation. The electronic switching part 15 generates a pulse signal Eu which contains the data pulses from the preamplifier 9 and comparison pulses for transmission to the surface. The seeker 17 generates a signal every time the probe passes a joint of the casing 21 in the borehole.

In the F i g. 2A and 2B, the armored multi-conductor coaxial cable 25 is shown in detail. The coaxial cable 25 has an inner conductor 28, which consists of 19 stranded tin-copper wires, the one 0.28 mm (0.0112 ") in diameter and from a coaxial isolator 30 are surrounded, the z. B. consist of a material such as polytetrafluoroethylene can. Around the insulator 30 six conductor groups 31 to 36 are spirally wound, each of seven Non-stranded conductors consist of tin-copper wires, 0.28 mm (0.0112 ") each. The conductor groups 31 to 36 are separated from one another by isolations 39 that are 0.28 mm (0.0112 ") in diameter have and can also be made of polytetrafluoroethylene. A reinforcement 47, which from 18 Strands of 1.09 mm (0.43 ") thick galvanized steel wire is twisted around the Conductor groups 31 to 36 and the insulation 39 arranged around the reinforcement 47 is covered with an anti-corrosion coating coated Another armor 48 consisting of 18 strands of a 1.50 mm (0.59 ") thick galvanized steel wire that is twisted to the left and also coated with an anti-corrosion coating is arranged around the armouring 47 around the armoring 47 of the conductor groups Separate 31 to 36 is another coaxial insulator 41, which is also made of polytetrafluoroethylene can be made, arranged between the conductor groups and the reinforcement 47 The number of individual Conductors in the conductor groups 31 to 36 as well as the conductive and non-conductive materials can of course to be changed.

The in F i g. 3, the distribution circuit 20 shown in detail has a multiplicity of capacitors 50, 51, 52, 53 and 56, which are connected between the conductors 31 and 32, 32 and 33, 33 and 34, 34 and 35 and 35 and 36 or conductor groups 31 to 36 are connected so that these interconnected conductor groups form a shield; but for direct current signals or low frequency alternating current signals the conductor groups 31 to 36 act as individual conductors. A capacitor SS connects the conductor 35 to the earth potential 58 so that the alternating current shield is effectively earthed. The armoring 48 is also grounded. The capacitors of the distribution circuit 30 improve the high-frequency coupling between the conductor groups 31 to 36 and the ground potential 58.

The conductors 31A 32Λ connected to the viewfinder 17 (Fig. 1) are connected to conductor groups 31 and 32

ίο of the coaxial cable 25 for the transmission of the viewfinder signals connected to the electronic device arranged above ground. The conductors 33/4 and 34/4 are with the Conductor groups 33 and 34 connected to a high and a low DC voltage to the crystal detector 8 to direct. The conductor groups 35 and 36 are connected to the earth potential, since they are in the present Invention are not needed, but are available for another borehole logging system. The head 28 is made with the high frequency properties of the

Shielding used to transmit high-frequency data signals to the surface.

The coaxial cable 25 is via a Rullin device 60 passed the a signal to a measuring strip recorder 61 transmitted that with the depth of the Measuring probe 1 in the borehole corresponds to the coaxial cable 25 is wound on a cable drum 65 and connected to collector rings 66. The collector rings 66 are connected to another cable 70 carried by be of the same design as the coaxial cable 25

JO can, although it is not a requirement. However, if the cable 70 is not the same type as the coaxial cable 25 must be provided 48 B for a corresponding ground.

One line 288 of the cable 70 is connected to a

J5 resistor 73 and a capacitor 74 connected. A high voltage Sirom source 87 transmits the DC voltage Vi to conductor 285 through the resistor 73.

The pulse signal Ei passes through the capacitor 74 and is transmitted to a pulse height adjustment device 80. The adjustment device 80 transmits a signal to a spectrum stabilizer 81. The spectrum stabilizer 81 controls the adjustment device 80 by means of a control signal in order to increase the amplitude of the pulses Ei generated by the adjustment device 80 according to the comparison pulses im Pulse signal Ei generated to adjust. The spectrum stabilizer 81 receives a comparison voltage V ₄ and compares the comparison pulses with the comparison voltage Kt in order to transmit the control signal to the adjustment device 80.

The pulses Ei from the adjustment device 80 are transmitted to a pulse processing circuit 83

Vi A low voltage power source 88 _{applies a positive DC voltage V 2} to conductor 34A. Another low voltage power source 89 applies a negative DC voltage V] to conductor 33S. Between the conductor 31 and B 32SS is connected in a finder meter 90th The outputs of the pulse processing circuit 83 and the output of the viewfinder meter 90 are fed to the recorder 61 for recording the information.

For this purpose 2 sheets of drawings

Claims (7)

Claims; 1. Borehole measuring arrangement, in particular to determine the characteristics of the drilled holes Earth formations by emitting fast neutrons, with a measuring probe, the at least two generates signals corresponding to the borehole conditions, one of which has a high frequency has, an armored multi-conductor coaxial cable with an inner conductor, a first insulator arranged coaxially therewith, a shielding from the inner conductor is separated by the first insulator, a second coaxial insulator and one outer armor made of conductive material, separated from the shield by the second insulator is separated, the high-frequency signal being fed to the inner conductor of the coaxial cable, and with an electronic device arranged above ground for processing the data from the measuring probe Signals transmitted via the coaxial cable and for generating output signals which correspond to the conditions determined in the borehole, characterized in that, that the shielding is formed by groups of conductors (31-36) which are isolated from one another, and that in the measuring probe (1) a distribution circuit (20) is provided, which the high-frequency signal to the Inner conductor (28) and the conductor groups (31-36) of the coaxial cable (25) and another in the Measuring probe (1) generates a low frequency signal from one of the conductor groups (31-36) and the outer one Reinforcement '47; 48) feeds 2. Arrangement according to claim 1, wherein DC voltages from the surface arranged electronic equipment are fed to the measuring probe via the conductors of the coaxial cable, characterized in that the above-ground electronic device has three DC voltage sources (87; 88; 89), each of the DC voltages generated across one of the conductor groups (31-36) and the outer armoring (47; 48) of the measuring probe (1) can be fed. 3. Arrangement according to one of the preceding claims, characterized in that the distribution circuit (20) has a plurality of capacitors (50-53,56) which are connected to the conductor groups (31-36) are linked in terms of circuitry in such a way that the conductor groups (31-36) are interconnected with regard to high-frequency alternating current signals, with regard to low-frequency alternating current signals and direct voltages, however, they are separated from one another are, and that a capacitor (56) for high-frequency connection of the conductor groups (31-36) with earth potential one of the conductor groups (31-36) with the outer one lying on earth potential Armoring (47; 48) of the coaxial cable (25) connects. 4. Arrangement according to one of the preceding claims, characterized in that the conductor of the conductor groups (31-36) are essentially the same distance from the inner conductor (28). 5. Arrangement according to one of the preceding claims, characterized in that the conductor groups (31-36) are separated from one another by a wire-shaped insulator (39). 6. Arrangement according to one of the preceding claims, characterized in that each Conductor group (31-36) consists of seven unsworn tin-copper wires each with a wire diameter of 0.28 mm. 7. Arrangement according to one of the preceding claims, characterized in that the insulators (30 j 39; 41) of the coaxial cable (25) Polytetrafluoroethylene exist.